Pixel optimization for color

ABSTRACT

A macro pixel is provided. The macro pixel includes at least two color pixel elements. Each color pixel element includes a photoreceptor that in response to receiving light, generates an output signal that is indicative of the quantity of light photons of a color are received. Each of the color pixel elements are configured to receive a corresponding color. The photoreceptor of each color pixel element has a geometry and a responsivity to light that is a function of the geometry of the photoreceptor such that the responsivity of the output signal of the photoreceptor to the corresponding color is controllable by changing the geometry. The geometries of the photoreceptors are selected so that a predetermined relative sensitivity to each color is obtained

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of the filing date of U.S. provisional application No. 60/223,396 filed Aug. 7, 2000, the content of which is herein incorporated by reference in its entirety.

TECHNICAL FIELD

The present invention relates generally to image sensors and in particular, to complementary metal oxide semiconductor (CMOS) color image sensors.

BACKGROUND AND SUMMARY

Conventional imaging circuits typically use active pixel sensor cells to convert light energy into electrical signals. Each of the active pixel sensor cells generally includes a photoreceptor with several associated transistors that provide several pixel functions including signal formation, reset, and amplification. In a color imager, separate pixels are used for receiving each band of light, such as those corresponding to the primary colors, red, green, and blue. The responsivity of a pixel varies with the specific color of light that is being captured. For example, in a system employing red, green, and blue color pixels, having a uniform integration time for each pixel and a typical scene being imaged; the output signal of a pixel for an amount of light received will vary as a function of the responsivity of the pixel to the imaged color. Correspondingly, the signal to noise ratio (S/N) of the pixels will vary as a function of the responsivity to the imaged color. Typically, blue pixels are less responsive than red and green pixels, causing the S/N of the blue pixels to be less than the S/N of red and green pixels. In addition to differences in S/N, there are differences in saturation of the pixels. Specifically, when capturing an image with equal amounts of red, green, and blue light, the storage capacitance associated with the pixels having the greater sensitivity (the red and green pixels) will reach a maximum capacity of stored photoelectrons first, saturating the pixel.

Separate gain elements for corresponding spectral band channels can be used to equalize the output signals of the different color sensors to compensate for differences in responsivity. However, the gain elements increase the cost of the imager, require increased space, and have no effect on the differences in S/N for the different color pixels.

A macro pixel is provided. The macro pixel includes at least two color pixel elements. Each color pixel element includes a photoreceptor that in response to receiving light, generates an output signal that is indicative of the quantity of light photons received. A first of the color pixel elements is configured to receive a first color. The photoreceptor of the first of the color pixel elements has a first geometry and a responsivity to light that is a function of the first geometry of the photoreceptor such that the responsivity of the output signal of the photoreceptor to the first color is controllable by changing the first geometry. A second of the color pixel elements is configured to receive a second color. The photoreceptor of the second of the color pixel elements has a second geometry and a responsivity to light that is a function of the second geometry such that the responsivity of the output signal of the photoreceptor to the second color is controllable by changing the second geometry.

The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims.

DESCRIPTION OF DRAWINGS

FIG. 1 is a two-dimensional view of a color pixel assembly in accordance with the principles of the invention;

FIG. 2 is a two-dimensional view of a first series of color pixel elements;

FIG. 3 is a two-dimensional view of a second series of color pixel elements;

FIG. 4 is a set of graphs illustrating data associated with first and second series of color pixel elements;

FIG. 5 is a view of a pair of color pixel elements with corresponding microlenses; and

FIG. 6 is a two-dimensional view of a series of color pixel elements having active switches.

Like reference symbols in the various drawings indicate like elements.

DETAILED DESCRIPTION

An embodiment of a color imaging system 10 in accordance with the teachings of the invention is shown in FIG. 1. The color imaging system 10 includes an array of macro pixels 12, each converting received light into an electrical output signal. Each macro pixel 12 is preferably comprised of two green pixels 14 a and 14 b, a red pixel 18, and a blue pixel 16 that are configured in a Bayer pattern. Although a Bayer pattern pixel configuration is preferable, other pixel configurations that include two or more different color pixels including non-primary colors may be used.

The output signal of each color pixel is described by the following equation: V _(n) αphi _(n) *T _(n) *A _(n) *eta _(n) *G _(n) where n=1, 2, 3 . . . is the spectral band (e.g., 3 bands in the case of RGB), phi_(n) is the flux per unit area of each pixel, T_(n) is the transmission of each spectral band filter, A_(n) is the collection area of each pixel, eta_(n) is the quantum efficiency of each pixel, and G_(n) is the conversion gain of each pixel.

The invention may compensate for differences in responsivity between different color pixels (e.g. red versus green), to control the relative sensitivity of the signal outputs, V_(n), to phi_(n), while maintaining relatively equal pixel area for each color pixel. To compensate for differences in responsivity, the shape of the photoreceptor, e.g. the shape of the photodiode, for each type of color pixel, is adjusted. The photodiode shapes are selected so that the relative sensitivity of V_(n) to phi_(n) for the signal outputs is a predetermined ratio such as 1:1:1 for a CMOS RGB color image system.

Other photoreceptors such as n+ diffusion photodiodes, standard n-well photodiodes, and n-well photodiodes with a covering insulating field oxide as described in U.S. Pat. No. 6,040,592, p+ diffusion photodiodes, p-well photodiodes, and p-well photodiodes with a covering insulating field oxide, photogates, and other devices may be used. The generation of photocurrent in both the diffusion and well type photodiodes is similar. In each, a depletion region is formed across and near the p-n junction formed by the substrate and the diffusion area/well. Incident photons pass through an open portion of the photodiode surface area and impinge on the depletion area, generating photoelectrons. The generated photoelectrons are accumulated on the capacitance formed by the depletion area of the photodiode. The photoelectrons are swept out as a photocurrent when a reverse voltage is applied across the p-n junction.

FIGS. 2 and 3 show a two-dimensional view of a series of color pixels 20 a-20 h. The series of color pixels 20 a-20 h is used for matching the light sensitivity of different pixel configurations to the light color that a pixel measures. Although eight pixel configurations are chosen for the present example, any number of pixel configurations may be chosen. Each of the color pixels 20 a-20 h in the series is constructed to have a pixel area that is substantially a constant, in this case about 4.4*4.4 sq. um., with differing types of photodiodes 22 a-22 h that have varying shapes. The geometric shape and type of the photodiodes 22 a-22 h is varied to determine which color pixels 20 a-20 h to match with which colors to obtain output signals having a predetermined light sensitivity. In this example, color pixels 20 a-20 d are selected to have n-well photodiodes with variable diameter collector areas that are spaced a predetermined distance from the sidewall of the color pixel. Color pixels 20 e-20 h are selected to have n+ diffusion photodiodes in which the area of the collector is varied and the distance of the photodiode from the sidewall is controlled. The spectral responsivity versus wavelength and quantum efficiency versus wavelenth for each of the color pixels may be measured. In addition to varying the surface area of the collectors, other portions of the photodiode geometry that may be varied include the depth of the diffusion or well, and the spacing from the sidewall of the color pixel 20.

FIG. 4 shows graphs of the measured spectral responsivity versus wavelength and quantum efficiency versus wavelength of the eight color pixels 20 a-20 h are shown. The quantum efficiency, QE, is computed with respect to the total sensor area. As the photodiode area gets larger, the QE increases. In general, due to inherent advantages of N-well design over N+ diffusion photodiodes, N-well pixels demonstrate equal or lower capacitance and, correspondingly, equal or higher gain. Also, the capacitance is greater for pixels with larger photodiode area and longer sidewall perimeter. Also, N-well photodiodes show a higher QE and lower dark current density than the N+-diffusion photodiodes. Based on the measured data, color pixels are selected for each spectral band.

FIG. 1 shows the illustrated macro pixel configured to have a 1:1:1 relative sensitivity for a RGB CMOS imager 10. The macro pixel 12 includes color pixel 20 b for the green color pixels 14 a and 14 b, color pixel 20 a for the blue color pixel 16, and color pixel 20 c for the red color pixel 18. The macro pixel 12 may alternatively include color pixel 20 f for the green color pixels 14 a and 14 b, color pixel 20 d for the blue color pixel 16, and color pixel 20 h for the red color pixel 18.

FIG. 5 shows a pair of color pixel elements 30 and 32 with corresponding microlenses 34 and 36. Using a microlens improves the fill factor of a pixel. The microlens redirects light that would have reached the edges of the pixel into a focal area such as the center of the pixel or the photodiode collector area. By redirecting the light from the edges, the quantum efficiency for a color pixel element remains constant for different photodiode shapes and sizes. To vary the responsivity of a pixel element having a microlens, the conversion gain, G_(conv), may be varied. One method of varying G_(conv), is to vary the photodiode collector area, since G_(conv), is inversely proportional to the collector area.

FIG. 6 shows a two-dimensional view of a series of color pixel elements with a first alternate embodiment of the present invention. The pixels 20 i-20 k include n+ diffusion photodiodes in which the area 22 i-22 k of the collector may be actively varied by controlling one or more switches 23 i-23 k. By activating one of the switches 23 i-23 k the geometry of the photodiodes changes, causing the responsivity of the corresponding pixels 20 i-20 k to change in a controlled manner. The switches 23 i-23 k may be actively controlled during normal operation or may be fusible links that are set during a configuration procedure.

A number of embodiments of the invention have been described. It is expressly intended that the foregoing description and accompanying drawings are illustrative of preferred embodiments only, not limiting, and that the true spirit and scope of the present invention will be determined by reference to the appended claims and their legal equivalent. It will be equally apparent and is contemplated that various modifications and/or changes may be made in the illustrated embodiments without departure from the spirit and scope of the invention. 

1-24. (canceled)
 25. A pixel sensor cell comprising: a photodiode; and one or more switches positioned relative to the photodiode for changing the light collecting geometry of the photodiode.
 26. The pixel sensor cell of claim 25, wherein: the switches are operable to change the geometry of a photon collector associated with the photodiode.
 27. The pixel sensor cell of claim 26, wherein: the geometry change comprises a change of the surface area of the photon collector.
 28. The pixel sensor cell of claim 25, wherein: the switches are operable to change a photon collection area of said photodiode by changing a distance between an applicable part of the photodiode and a boundary of the pixel sensor cell.
 29. The pixel sensor cell of claim 25, wherein: the switches comprise fusible links.
 30. The pixel sensor cell of claim 25, wherein: the switches are actively controllable during operation of the pixel cell.
 31. The pixel sensor cell of claim 25, wherein: the switches are operable to change the response of the pixel to receiving light of a certain color.
 32. The pixel sensor cell of claim 32, wherein: the switches are operable to cause the response of the pixel to receiving light of a first color to correspond with the response of a second pixel to receiving light of a second color.
 33. An imager comprising: an array of pixel cells, at least one of said pixel cells comprising a photodiode and one or more switches associated with the photodiode; and circuitry for changing the geometry of the photodiode by activating the switches.
 34. The imager of claim 33, wherein: the geometry of the photodiode is changeable by a change in the geometry of a photon collector associated with the photodiode.
 35. The imager of claim 34, wherein: the geometry of the photon collector associated with the photodiode is changeable by a change in the surface area of the photon collector.
 36. The imager of claim 33, wherein: the circuitry is operable to activate the switches during operation of the array.
 37. The imager of claim 33, wherein: the switches comprise fusible links.
 38. The imager of claim 33, wherein: the circuitry is operable to change the response of the pixel to receiving light of a certain color.
 39. The imager of claim 33, wherein: the circuitry is operable to cause the response of the pixel to receiving light of a first color to correspond with the response of a second pixel to receiving light of a second color.
 40. A method of controlling a pixel sensor cell comprising: varying the geometry of a photodiode of the pixel sensor cell by controlling one or more switches associated with the photodiode that are capable of varying said geometry.
 41. The method of claim 40, wherein: the varying the geometry of the photodiode comprises changing the geometry of a photon collector associated with the photodiode.
 42. The method of claim 41, wherein: the changing the geometry of a photon collector associated with the photodiode comprises changing a surface area of the photon collector.
 43. The method of claim 40, further comprising: actively varying the geometry of the photodiode during operation of the pixel sensor cell.
 44. The method of claim 40, wherein: the varying the geometry of the photodiode comprises changing the response of the pixel sensor cell to receiving light of a certain color.
 45. The method of claim 44, wherein: the changing the response of the pixel sensor cell comprises causing the response of the pixel sensor cell to receiving light of a first color to correspond with the response of a second pixel sensor cell to receiving light of a second color. 